An experimental and theoretical study of magnetocaloric effect in Nd0.5Dy0.5FeO3

Singh, Ankita; Rajput, Sakshi; Padmanabhan, B.; Kaushik, Kedarsh; Anas, Mohd; Maitra, T.; Malik, V. K.

doi:10.1088/1361-648x/ab22e7

Cited by 9 publications

(6 citation statements)

References 41 publications

(81 reference statements)

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“…The compounds and orthoferrites containing Nd element usually show excellent magnetocaloric effect (MCE), , so we have also investigated the property of single crystal Nd 0.8 Pr 0.2 FeO 3 . In Figure , the representative isothermal magnetization curves are plotted when the magnetic fields along the a - and c -axes gradually increase to 70 kOe under different temperatures.…”

Section: Resultsmentioning

confidence: 99%

“…The maximum value of −ΔS m of the ErFeO 3 polycrystal 52 is 7.4 J/ kg•K, that of the DyFeO 3 polycrystal 52 is 11.4 J/kg•K, and that of the TmFeO 3 single crystal 42 is 11.93 J/kg•K. For rare-earthdoped compounds, 48 the maximum −ΔS m of Nd 0.5 Dy 0.5 FeO 3 is 10.4 J/kg•K, which is closed to the value of DyFeO 3 . Nevertheless, there are few reports on the magnetocaloric effect of NdFeO 3 single crystals and rare-earth-doped single crystals, and our results may fill the gap effectively in this field and can provide potential possibilities for the application of magnetic refrigeration materials.…”

Section: Magnetocaloric Effectmentioning

confidence: 96%

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Pr-Doping Effect on Spin Switching in Nd_0.8Pr_0.2FeO₃ Single Crystal

Sun,

Song,

Zhu

et al. 2023

J. Phys. Chem. C

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We have prepared single crystal Nd 0.8 Pr 0.2 FeO 3 by using optical floating zone method and investigated the Pr-doping effect on its magnetic properties in detail. Pr-doping with a ratio of 20% at Nd site in NdFeO 3 lowered the spin reorientation transition (SRT) temperature range of the undoped compounds from 107 to 170 K to 74−110 K, while the SRT type keeps the same; that is, the spin configuration of Fe sublattice changes from Γ 4 (G x , A y , F z ) to Γ 2 (F x , C y , G z ). Unlike the previous research on Nd 0.5 Pr 0.5 FeO 3 , 20% Pr 3+ doping exhibits more excellent properties in spin switching (SSW). There are two events of type-I and one event of type-II SSW observed in Nd 0.8 Pr 0.2 FeO 3 , and more interestingly, the type-I SSW in field cooled cooling (FCC) mode has not yet been observed in the parent single crystal NdFeO 3 . Besides, the type-II SSW can only be found at low temperatures when the magnetic field is below 100 Oe. When the applied field is 70 kOe, an significant magnetic entropy change (−ΔS m ) observed in the sample is 8.07 J/kg•K at 3 K. These results offer a better understanding to the doped magnetic anisotropy in RFeO 3 , and provide new possibilities in the application of magnetic switching materials under low magnetic fields of about tens of Oersted (Oe).

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Section: Resultsmentioning

confidence: 99%

Section: Magnetocaloric Effectmentioning

confidence: 96%

Pr-Doping Effect on Spin Switching in Nd_0.8Pr_0.2FeO₃ Single Crystal

Sun,

Song,

Zhu

et al. 2023

J. Phys. Chem. C

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“…Some models analyze the MCE using different methods. Recently, the properties of MCE were studied by several theoretical methods, namely, mean-field theory (MFT) [20][21][22][23][24][25][26][27], effective-field theory (EFT) [28][29][30][31][32][33], Monte Carlo (MC) simulation [34][35][36][37][38][39] and first-principles calculations [40][41][42].…”

Section: Introductionmentioning

confidence: 99%

Theoretical analysis of magnetic properties and the magnetocaloric effect using the Blume-Capel model

Oliveira¹,

Morais²,

Santos³

et al. 2022

Condens. Matter Phys.

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This work investigates the magnetic properties and the magnetocaloric effect in the spin-1 Blume-Capel model. The study was carried out using the mean-field theory from the Bogoliubov inequality to obtain the expressions of free energy, magnetization and entropy. The magnetocaloric effect was calculated from the variation of the entropy obtained by the mean-field theory. Due to the dependence on the external magnetic field and the anisotropy included in the model, the results for the magnetocaloric effect provided the system with first-order and continuous phase transitions. To ensure the results, the Maxwell relations were used in the intervals where the model presents continuous variations in magnetization and the Clausius-Clapeyron equation in the intervals where the model presents discontinuity in the magnetization. The methods and models for the analysis of a magnetic entropy change and first-order and continuous magnetic phase transitions, such as mean-field theory and the Blume-Capel model, are useful tools in understanding the nature of the magnetocaloric effect and its physical relevance.

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“…Rare-earth orthoferrites materials RFeO 3 (R= rareearth ion), have shown potential for technologically relevant applications via observation of spin switching, spontaneous exchange bias and optically controlled ultrafast spin dynamics [1][2][3][4][5][6][7]. Additional important properties include large linear magneto-dielectric effect, spontaneous ferroelectric polarization, mutilferroicity, and magnetocaloric effect [8][9][10][11][12][13].…”

Section: Introductionmentioning

confidence: 99%

“…Recent study by Wang et al [45] observed a long-to short-range ordering transition of Dy 3 concurrent to the magnetic field (along the c-axis) induced spin reorientation of the Fe 3+ sublattice. The magnetic field induced short range ordering of the Dy 3+ moments is responsible for the observed multiferroic phase induced by external magnetic field [10,45] In addition to the pure orthoferrites, doping and/or substitution at the Fe and/or R sites shows interesting variations in the structural, magnetic, and electronic properties, while the fundamental characteristic of ortho-ferrites is still retained [12,[56][57][58][59][60][61]. For instance, doping at the Fe-site with Mn has been studied and resulted in a systematic decrease of the Néel temperature [56,61], structural distortion due to Jahn-Teller effect [62], and modifies the preferred direction of Fe 3+ spins due to single ion anisotropy of Mn 3+ ions [56,63].…”

Section: Introductionmentioning

confidence: 99%

Coexisting magnetic structures and spin-reorientation in Er$_{0.5}$Dy$_{0.5}$FeO$_{3}$: Bulk magnetization, neutron scattering, specific heat, and \emph{Ab-initio} studies

Rajput,

Balasubramanian,

Singh

et al. 2021

Preprint

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The complex magnetic structures, spin-reorientation and correlated exchange interactions have been investigate in Er0.5Dy0.5FeO3 using bulk magnetization, neutron diffraction, specific heat measurements and density functional theory calculations. The Fe 3+ spins order as G-type antiferromagnet structure depicted by Γ4(Gx, Ay, Fz) irreducible representation below 700 K, similar to its end compounds. The bulk magnetization data indicate occurrence of the spin-reorientation and rare-earth magnetic ordering below ∼75 K and 10 K, respectively. The neutron diffraction studies confirm an "incomplete" Γ4→ Γ2(Fx, Cy, Gz) spin-reorientation initiated ≤75 K. Although, the relative volume fraction of the two magnetic structures varies with decreasing temperature, both co-exist even at 1.5 K. At 8 K, Er 3+ /Dy 3+ moments order as c R y arrangement develop, which gradually increases in intensity with decreasing temperature. At 2 K, magnetic structure associated with c R z arrangement of Er 3+ /Dy 3+ moments also appears. At 1.5 K the magnetic structure of Fe 3+ spins is represented by a combination of Γ2+Γ4+Γ1, while the rare earth moments coexists as c R y and c R z corresponding to Γ2 and Γ1 representation, respectively. The observed Schottky anomaly at 2.5 K suggests that the "rare-earth ordering" is induced by polarization due to Fe 3+ spins. The Er 3+ -Fe 3+ and Er 3+ -Dy 3+ exchange interactions, obtained from first principle calculations, primarily cause the complicated spin-reorientation and c R y rare-earth ordering, respectively, while the dipolar interactions between rare-earth moments, result in the c R z type rare-earth ordering at 2 K.

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An experimental and theoretical study of magnetocaloric effect in Nd_0.5Dy_0.5FeO₃

Cited by 9 publications

References 41 publications

Pr-Doping Effect on Spin Switching in Nd_0.8Pr_0.2FeO₃ Single Crystal

Pr-Doping Effect on Spin Switching in Nd_0.8Pr_0.2FeO₃ Single Crystal

Theoretical analysis of magnetic properties and the magnetocaloric effect using the Blume-Capel model

Coexisting magnetic structures and spin-reorientation in Er$_{0.5}$Dy$_{0.5}$FeO$_{3}$: Bulk magnetization, neutron scattering, specific heat, and \emph{Ab-initio} studies

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An experimental and theoretical study of magnetocaloric effect in Nd0.5Dy0.5FeO3

Cited by 9 publications

References 41 publications

Pr-Doping Effect on Spin Switching in Nd0.8Pr0.2FeO3 Single Crystal

Pr-Doping Effect on Spin Switching in Nd0.8Pr0.2FeO3 Single Crystal

Theoretical analysis of magnetic properties and the magnetocaloric effect using the Blume-Capel model

Coexisting magnetic structures and spin-reorientation in Er$_{0.5}$Dy$_{0.5}$FeO$_{3}$: Bulk magnetization, neutron scattering, specific heat, and \emph{Ab-initio} studies

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An experimental and theoretical study of magnetocaloric effect in Nd_0.5Dy_0.5FeO₃

Pr-Doping Effect on Spin Switching in Nd_0.8Pr_0.2FeO₃ Single Crystal

Pr-Doping Effect on Spin Switching in Nd_0.8Pr_0.2FeO₃ Single Crystal